Abstract:

Quantum cascade (QC) lasers are a fundamentally new semiconductor laser source designed by methods of `bandstructure engineering' and realized by molecular beam epitaxy (MBE). One of their most intriguing features is the cascading scheme, which results in the lasers' intrinsic potential for high optical output power. QC-lasers with varying numbers, from one to 75, of cascaded active regions and injectors have been studied. Pulsed peak output power levers of greater than or equal to 500 mW at room temperature and greater than or equal to 1 W at 200 K have been obtained for a 2.25 mm long and approximate to 12 mu m wide Fabry-Perot laser-stripe with 75 cascades. In continuous wave operation, 200 mW have been measured from one facet at 80 K and still 60 mW at 110 K, both from lasers with 30 stages. These lasers have an InP top cladding layer grown by MBE using solid source phosphorous. Widely tunable single-mode QC-distributed feedback (DFB) lasers have been fabricated in the wavelength range around 8.5 mu m. A side-mode suppression ratio of 30 dB and a 140 nm single-mode tuning range (thermal tuning between 10 and 320 K for lasers operated in pulsed mode) have been obtained. QC-DFB lasers driven in cw-mode display a tunability of approximate to 70 nm as a result of thermal tuning between 20 and 120 K. (C) 2000 Elsevier Science S.A. All rights reserved.

Notes:

IUMRS International Conference of Advanced Materials, BEIJING, PEOPLES R CHINA, JUN 13-18, 1999